Method for Forming a Notched Gate Insulator for Advanced MIS Semiconductor Devices and Devices Thus Obtained

ABSTRACT

Methods of providing a semiconductor device with a control electrode structure having a controlled overlap between control electrode and first and second main electrode extensions without many spacers are disclosed. A preferred method provides a step of etching back an insulating layer performed after amorphizing and implanting the main electrode extensions. Preferably, the step that amorphizes the extensions also partly amorphizes the insulating layer. Because etch rates of amorphous insulator and crystalline insulator differ, the amorphized portion of the insulating layer may serve as a natural etch stop to enable even better fine-tuning of the overlap. Corresponding semiconductor devices are also provided.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 11/636,817, filed on Dec. 11, 2006, which is a divisional application of U.S. patent application Ser. No. 10/966,152, filed on Oct. 15, 2004, now U.S. Pat. No. 7,157,356, each of which are hereby incorporated by reference in their entirety.

TECHNICAL FIELD OF THE INVENTION

The present invention relates to a method for forming a notched gate insulator semiconductor device and the device thus obtained. More particularly, the present invention relates to a method for the formation of a semiconductor device structure comprising first and second main electrode extensions, e.g. source and drain extensions, with controllable control electrode, e.g. gate electrode, overlap.

BACKGROUND OF THE INVENTION

The scaling of Metal-Oxide-Semiconductor (MOS) or Metal-Insulator-Semiconductor (MIS) transistor devices has reached a point where the length of the gate electrode is only a few tens of nanometers. Requirements for the source/drain extensions (the ultra-shallow junctions USJ) are mainly three-fold, i.e. very high activation (for end-of-the-roadmap devices above the solid solubility limit), ultra-shallow (towards less than 10 nm) and a very high lateral abruptness (1-2 nm/decade). The last one is also dictated by another requirement, the gate leakage level at the junction's overlap with the gate region. There is a trade-off between having no overlap for minimal gate leakage and enough overlap for optimal gate action on the junction. This trade-off is one of the major problems in scaling down the planar devices.

In U.S. Pat. No. 6,274,446 a method is described for the fabrication of a semiconductor device comprising abrupt source/drain extensions with controllable gate electrode overlap. The method comprises the steps of forming a gate structure on a semiconductor substrate, followed by forming an oxide layer on the gate and substrate. First, sidewall spacer regions are formed on the sides of the gate structure. Deep source/drain regions that do not overlap with the gate electrode are implanted in the semiconductor substrate. In order to create overlap, second spacer regions of silicon are formed on the sides of the sidewall spacer regions. Upper regions of the gate structure and the sidewall spacer regions are silicided in order to electrically connect them. Also portions of source/drain extension regions in the semiconductor substrate adjacent the gate structure are silicided.

A first disadvantage of the method described in the above document is the number of extra steps required, i.e. “extending” the gate electrode by means of depositing silicon side wall spacers, etching back the spacers and connecting the spacers to the body of the original gate electrode.

Another disadvantage of the above method is that by the inevitable presence of an oxide layer between the body of the gate electrode and the silicon sidewall spacers, the overall gate electrode is in fact a discontinuous body of material with deleterious effects on the properties thereof.

In EP 1 089 344 an insulated gate field effect transistor and a method of making the same are described. The device comprises a first gate insulating film, such as TiO₂, which is formed on a channel region. A gate electrode is formed on the first gate insulating film. Source and drain regions are formed in a surface portion of a p-well region. The gate electrode is formed such that it may partially overlap the source/drain region. The TiO₂ film is subjected to either isotropic or anisotropic etching so that a portion of the TiO₂ film which lies on the source/drain region, may be removed, hereby forming a recess underneath the gate electrode.

In JP 11 163323 a semiconductor device comprising an insulating layer, a gate electrode and a source and drain is described. By adjusting the etching time of an etching process of the insulating layer, the overlap length between the gate electrode and the source and drain can be adjusted. Etching of the insulating layer is performed by wet chemical etching in a 0.3% HF solution.

A disadvantage of EP 1 089 344 and JP 11 163323 is that the etching process of the insulating layer can not be controlled very well. Nowadays, scaling down of electric and electronic devices plays a very important role in semiconductor processing. With the methods described in EP 1 089 344 and JP 11 163323 it will be difficult to form, in a controllable way, shallow recesses in devices having small dimensions.

SUMMARY OF THE INVENTION

Certain aspects of the present invention provide a simple method of providing controlled overlap between first and second main electrode extensions, e.g. source and drain extensions, and the main electrode, e.g. gate electrode, of a semiconductor device structure.

One aspect of the invention provides a semiconductor device structure comprising an insulating layer provided on a semiconductor substrate, a control electrode, e.g. a gate, provided on the insulating layer, and a first main electrode extension, e.g. source extension, and a second main electrode extension, e.g. drain extension, in the substrate. The electrodes have an overlap with the control electrode. The insulating layer comprises a recess near the first main electrode extension and near the second main electrode extension with respect to the control electrode. The recess has a depth of between about 0.5 and 5 nm. An advantage of the recess near first and second main electrode extension is that the overlap between the control electrode and the first and second main electrode extensions can easily be controlled by means of changing the depth of the recess during the processing of the device. The depth of the recess may be less than a width of an overlap between the control electrode and the first main electrode extension and/or the second main electrode extension.

The semiconductor device structure according to the present invention may have a control electrode with a length of less than about 100 nm, preferably about 50 nm or less.

Furthermore, the semiconductor device structure of the present invention may preferably have an overlap between the insulating layer and the first and second main electrode extensions of between about 10 and 20% of the length of the control electrode. The overlap between the control electrode and the first and second main electrode extensions may preferably be between 10 and 20% of the length of the control electrode.

In the device of the present invention the insulating layer may be made of a material comprising silicon oxide. The control electrode may be made of material comprising silicon. The control electrode may comprise polycrystalline material, e.g. polysilicon.

An aspect of invention provides a method for processing a semiconductor device structure comprising providing an insulating layer and a control electrode, e.g. gate, onto a substrate, amorphizing a region to be implanted in the substrate to form first and second main electrode extensions, and amorphizing part of the insulating layer by means of accelerated ions under a first angle with respect to a direction perpendicular to the substrate, implanting a first main electrode extension, e.g. source extension, and a second main electrode extension, e.g. drain extension, under a second angle with respect to a direction perpendicular to the substrate, etching back part of the insulating layer in order to reduce capacitive overlap between the control electrode and the first and second main electrode extensions to a reduced but non-zero overlap level, hereby forming recesses. The border between the amorphized part and the non-amorphized part of the control electrode insulating layer acts as an etch stop. Hence, by changing the magnitude of the part of the insulating layer that is amorphized, the depth of the recesses may be changed. Etching back may be performed by a dip in a HF solution with a concentration between about 0.1 and 10%.

In an embodiment of the present invention, the first angle, under which amorphizing of the first and second electrode extension regions and of part of the insulating layer occur, and the second angle, under which implantation of first and second main electrode extensions occur, may substantially be the same. In another embodiment, the angles may be different. In either of the above embodiments, the first and the second angle may vary between about 0° and 45° with respect to a direction perpendicular to the plane of the substrate.

The method may furthermore comprise activating the first and second main electrode extensions. In an embodiment of the present invention, activation of the first and second main electrode extensions may be performed by an annealing step selected from the group consisting of rapid thermal annealing, flash rapid thermal annealing, solid phase epitaxy regrowth or laser thermal annealing. In a preferred embodiment, the activation step is performed after the step of etching back, because annealing may remove the amorphized parts of the gate insulating layer. This results in reduced control over the overlap between the control electrode and the first and second main electrode recesses because the border of the amorphized parts of the gate layer and the non-amorphized parts of the gate insulator layer acts as an etch stop.

These and other characteristics, features and advantages of the present invention will become apparent from the following detailed description, taken in conjunction with the accompanying drawings, which illustrate, by way of example, the principles of the invention. This description is given for the sake of example only, without limiting the scope of the invention. The reference figures quoted below refer to the attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is schematic cross-sectional view of a MOSFET device during an extension implant.

FIG. 2 is a schematic cross-sectional view of the device of FIG. 1 after etching the control electrode, e.g. gate, insulating layer.

FIGS. 3A-3F are schematic cross-sectional views illustrating a method of forming a semiconductor device

In the different figures, the same reference figures refer to the same or analogous elements.

Description of Illustrative Embodiments

The present invention will be described with respect to particular embodiments and with reference to certain drawings but the invention is not limited thereto but only by the claims. The drawings described are only schematic and are non-limiting. In the drawings, the size of some of the elements may be exaggerated and not drawn on scale for illustrative purposes. Where the term “comprising” is used in the present description and claims, it does not exclude other elements or steps.

Moreover, the terms top, bottom, over, under and the like in the description and the claims are used for descriptive purposes and not necessarily for describing relative positions. It is to be understood that the terms so used are interchangeable under appropriate circumstances and that the embodiments of the invention described herein are capable of operation in other orientations than described or illustrated herein.

The method according to the invention may be used in many methods for fabricating semiconductor devices with insulated control electrodes, for example gates. In the description hereinafter, a method is described for manufacturing a device having a gate as control electrode and a source and a drain as first and second main electrodes.

In a next step a gate electrode 3 is formed. Therefore a conductive layer which may for example be a semiconductor layer such as e.g. Si, a metal layer such as e.g. gold, aluminum or copper, or an inorganic conductive layer such as an indium tin oxide (ITO) layer may be deposited on top of the gate insulating layer 2 by means of any suitable deposition technique such as for example vapor deposition, sputter deposition or spin coating. Subsequently, the deposited layer may be etched back to the form of an electrode. Therefore a mask is applied onto that part of the conductive layer, which will later form the gate electrode 3. The mask may be made of any suitable material, such as for example a polymer, which may be deposited onto the conductive layer by means of for example spin coating. The conductive layer is then etched, removing the part of the conductive layer which is not covered by the mask. The same masking step may also be used to etch the part of the gate insulating layer 2 which is not under the formed gate electrode 3. FIG. 3A illustrates a semiconductor device at this stage of the formation process. Therefore, an etching solution, which may etch both the conductive material of the gate electrode 3 and the insulating material of the gate insulating layer 2, is preferably used. In FIG. 1, the gate electrode 3 is shown as being (poly)crystalline but the invention is not restricted hereto.

In a next step a gate electrode 3 is formed. Therefore a conductive layer which may for example be a semiconductor layer such as e.g. Si, a metal layer such as e.g. gold, aluminum or copper, or an inorganic conductive layer such as an indium tin oxide (ITO) layer may be deposited on top of the gate insulating layer 2 by means of any suitable deposition technique such as for example vapor deposition, sputter deposition or spin coating. Subsequently, the deposited layer may be etched back to the form of an electrode. Therefore a mask is applied onto that part of the conductive layer, which will later form the gate electrode 3. The mask may be made of any suitable material, such as for example a polymer, which may be deposited onto the conductive layer by means of for example spin coating. The conductive layer is then etched, removing the part of the conductive layer which is not covered by the mask. The same masking step may also be used to etch the part of the gate insulating layer 2 which is not under the formed gate electrode 3. Therefore, an etching solution, which may etch both the conductive material of the gate electrode 3 and the insulating material of the gate insulating layer 2, is preferably used. In FIG. 1, the gate electrode 3 is shown as being (poly)crystalline but the invention is not restricted hereto.

In order to fulfill the above mentioned requirements, an additional step of amorphizing the region to be implanted is performed, according to the present invention, before the actual implanting of source and drain regions is performed. This step may also be referred to as pre-amorphization implant (PAI). PAI is a well controllable method which limits the depth to which implants can be made. Thereto, atoms, or more precisely ions, are implanted in a sufficient concentration to disrupt the originally perfect crystal lattice of the substrate 1, so that it becomes amorphous. Applying PAI will thus form regions of a shape like source extension and drain extensions 4, 5 in FIG. 1. The step of amorphizing the extension volume by bombarding under a suitable first angle ensures that a part of the accelerated ions used in the bombarding will pass through the part of the gate electrode 3 nearest the semiconductor substrate 1, and will hence form an amorphized volume 6, 7 showing overlap with the gate electrode 3. FIG. 3A illustrates amorphizing a first region of the substrate and a first region of the insulating layer by accelerating ions under an angle 10 with respect to a direction substantially perpendicular to the substrate, forming, in the illustrated example, amorphized volume 7 and an amorphized region which will form drain electrode 5. FIG. 3B illustrates amorphizing a second region of the substrate and a second region of the insulating layer by accelerating ions under an angle 11 with respect to the direction substantially perpendicular to the substrate, forming, in the illustrated embodiment, amorphized volume 6 and an amorphized region which will form source extension 4. In a PAI, atoms that in principle do not themselves influence the dopant concentration level, such as for example Si or Ge, are implanted in the region of the extensions 4, 5. For Ge, for example, this may occur at energies of approximately 8 to 20 keV, with concentrations between about 5.10e14 to 3.10e15 atoms/cm³ and under an angle of between for example 0° and 45°. To obtain a desired amorphization different conditions may be required for different kinds of semiconductors.

In order to fulfill the above mentioned requirements, an additional step of amorphizing the region to be implanted is performed, according to the present invention, before the actual implanting of source and drain regions is performed. This step may also be referred to as pre-amorphization implant (PAI). PAI is a well controllable method which limits the depth to which implants can be made. Thereto, atoms, or more precisely ions, are implanted in a sufficient concentration to disrupt the originally perfect crystal lattice of the substrate 1, so that it becomes amorphous. Applying PAI will thus form regions of a shape like source extension and drain extensions 4, 5 in FIG. 1. The step of amorphizing the extension volume by bombarding under a suitable first angle ensures that a part of the accelerated ions used in the bombarding will pass through the part of the gate electrode 3 nearest the semiconductor substrate 1, and will hence form an amorphized volume 6, 7. showing overlap with the gate electrode 3. In a PAI, atoms that in principle do not themselves influence the dopant concentration level, such as for example Si or Ge, are implanted in the region of the extensions 4, 5. For Ge, for example, this may occur at energies of approximately 8 to 20 keV, with concentrations between about 5.10e14 to 3.10e15 atoms/cm³ and under an angle of between for example 0° and 45°. To obtain a desired amorphization different conditions may be required for different kinds of semiconductors.

After PAI, the step of actual implanting the extension regions 4, 5 with the desired dopants may be performed. For example, boron atoms may be implanted at energies of about 0.5 keV with concentrations up to approximately 1.10e15 atoms/cm3. However, any kind of suitable implant energy, dose or dopant type may be used in this step. The step of implanting may be performed under a second angle, which, in some cases, may be substantially the same as the first angle. FIG. 3D illustrates implanting ions into the amorphized regions of the substrate to form a source extension 4 and a drain extension 5 by implanting ions using an angle 12 with respect to the direction substantial perpendicular to the substrate. It may thus be ensured that with the appropriate energy of the dopants, the dopants may be present in the amorphized region.

The direction of bombarding in order to amorphize and the direction for implanting may be chosen towards the gate electrode 3 in order to achieve overlap. This means that in principle two different directions are required for treatment of the source side and the drain side of the device. However, this does not entail additional masking steps, because the implants for source and drain differ anyhow, and the amorphizing step before the implanting step does not need any additional masking step. For example, the drain extension 5 may be implanted according to a direction indicated by arrows I in FIG. 1, including an angle a with a direction perpendicular to the substrate 1. In FIG. 1 this direction is indicated by the dashed line.

The angles and energies of the accelerated ions for amorphizing and for implanting of the dopants may be selected such that a desired overlap is realized. Selection of these quantities is interrelated and further depends on the type of semiconductor substrate 1 used.

During the PAI step, not only the semiconductor substrate 1 is amorphized. Also a part of the gate insulating layer 2 may, to a depth of for example a few nanometers, be amorphized due to the action of the amorphizing particles. In FIG. 1 this is shown as amorphous parts 6 and 7. This damage may be undone by annealing the semiconductor device during a further activation step, so that all of the gate insulating layer would be (poly)crystalline again. However, the damage caused in the gate insulating layer 2 by PAI may be further used during processing to achieve controllable overlap between extensions 4, 5 and the gate electrode 3 (see further).

After having performed the above steps, a structure like the one shown in FIG. 1 is the result. In a next step, a part of the gate insulating layer 2 is removed in order to reduce the capacitive overlap between gate electrode 3 and extensions 4, 5 to a reduced but non-zero overlap level. This may be done by means of etching, e.g. by means of a wet etch. The material of the gate insulating layer 2, i.e. a dielectric material in general, on the one hand, and the material of the gate electrode 3 and the semiconductor substrate 1 on the other hand are different. Therefore, an etchant may be selected which selectively etches the gate insulating layer 2 but not the other materials used. Furthermore, in one embodiment, the gate insulating layer 2 comprises amorphized parts 6, 7 and a non-amorphized or polycrystalline part. Because the etch rate of the amorphous gate insulator may differ from that of the (poly)crystalline gate insulator deeper under the gate 3, and in most cases may be higher, the border between the amorphous and polycrystalline gate insulator may be used as an etch stop. Hence, an etching solution may be required which only removes the amorphized parts 6, 7 of the gate insulating layer 2 and does not etch the polycrystalline part of the insulating layer 2.

For example, the etching step may be performed by dipping the semiconductor device structure in a HF solution, preferably with a concentration between about 0.1 and 10%, for example 0.2%, during a period between for example 1 second and 5 minutes. The type of etchant, concentration of the etching solution and etching time may depend on the depth required to etch or on the material that has to be etched. Therefore, this step of etching back the gate insulating layer 2 offers a good control over the overlap, for it is possible to select a relatively slow and therefore precise etching process. Alternatively, the gate insulating layer 2 may also be etched before the actual implant of the extensions 4, 5.

After PAI, the step of actual implanting the extension regions 4, 5 with the desired dopants may be performed. For example, boron atoms may be implanted at energies of about 0.5 keV with concentrations up to approximately 1.10e15 atoms/cm³. However, any kind of suitable implant energy, dose or dopant type may be used in this step. The step of implanting may be performed under a second angle, which, in some cases, may be substantially the same as the first angle. FIG. 3D illustrates implanting ions into the amorphized regions of the substrate to form a source extension 4 and a drain extension 5 by implanting imp using an angle 12 with respect to the direction substantial perpendicular to the substrate. It may thus be ensured that with the appropriate energy of the dopants, the dopants may be present in the amorphized region.

In FIG. 2, the recess 9 on the right hand side of the device is shown as having an etch depth e. The etch depth may for example be a few nanometers, preferably between 0.5 and 5 nm. The distance d represents the remaining overlap between drain extension 5 and gate insulating layer 2. The remaining overlap d between the gate insulating layer 2 and the drain extension 5 may preferably be between about 10 and 20%, for example 15%, of the length 1 of the gate electrode 3. The latter statement only applies for gate lengths below about 100 nm, preferably 50 nm or less. For larger gate lengths, a smaller overlap ratio may be selected.

A following step may be an activation step in order to activate the implanted dopants, i.e. to build the dopants into the crystal lattice of the semiconductor substrate 1. This step may also be referred to as a junction anneal step. The junction anneal step may be performed by annealing the device with for example high ramp rates. Preferred processes include rapid thermal anneal (RTA), flash rapid thermal anneal (fRTA), solid phase epitaxy (SPE) and laser thermal anneal (LTA). The type of anneal and the energy concerned may be selected according to the requirements of a specific device. In the present invention, it is preferred to perform this annealing step after etching the gate insulating layer thus forming the recesses 8, 9, because annealing may remove the “etch stop”, which was formed by PAI, by curing the gate insulating layer 2. Because of that, the control over the overlap between the gate electrode 3 and the source and drain recesses 8, 9 may disappear.

After thus forming a junction with controlled overlap and activating it, the processing of the semiconductor device structure may be finished with any desired subsequent step, depending on the kind of semiconductor device that has to be formed. For example, in a CMOS process, a spacer for deep source and drain implants may be deposited in for example a low temperature plasma enhanced chemical vacuum deposition (CVD) process in the form of an oxide, at a deposition temperature of for example 400° C. FIG. 3F illustrates a semiconductor device at this stage of the formation process, in which a spacer 10 has been deposited. The CVD oxide will not fill the recesses 8, 9 due to its course-grained porosity. Furthermore, any other desired subsequent step in the process of forming the semiconductor device may be performed.

In general, a balance has to be found between an overlap which is as small as possible to reduce parasitic capacitance and hot carrier effect, and an overlap which is big enough to ensure a quick response of the semiconductor device, i.e. a short switching time. The total overlap between source and drain extensions 4, 5 and the gate electrode 3 is represented by t in FIG. 2. With short gate lengths of less than about 100 nm it may be sufficient when the extensions 4, 5 overlap the gate electrode 3 for between about 10% and 20%, e.g. 15%, of the length of the gate electrode 3. Therefore, this method is particularly suitable for forming an overlapping extension 4, 5 for devices with very short gate lengths, because it gives the possibility to obtain a sufficient overlap without having to use diffusion techniques. Diffusion techniques suffer from less abrupt transitions between extensions 4, 5 and substrate 1 and are furthermore more difficult to control. In particular, it is very difficult to limit diffusion to an overlap of less than 10 nm. For very short gate lengths of for example 50 nm down to even 30 or 20 nm, this is a too large overlap and hence the diffusion technique is then no longer useful.

An advantage of aspects of the present invention is the simple way of tuning the overlap between the gate electrode 3 and source and drain extensions 4, 5, without the need for masks and/or spacers. This may reduce production time and hence production costs. Furthermore, the method of the present invention leads to strongly reduced gate leakage in the semiconductor device thus obtained.

It is to be understood that although preferred embodiments, specific constructions and configurations, as well as materials, have been discussed herein for devices according to the present invention, various changes or modifications in form and detail may be made without departing from the scope and spirit of this invention. 

1. A semiconductor device comprising: a first main electrode extension and a second main electrode extension formed in a semiconductor substrate; an insulating layer formed on the semiconductor substrate; and a control electrode formed over the insulating layer; wherein the insulating layer has an overlap with each main electrode extension and the insulating layer has a first unfilled recess near the first main electrode extension having a depth of less than a width of an overlap between the control electrode and the first main electrode extension and/or a second unfilled recess near the second main electrode extension having a depth of less than a width of an overlap between the control electrode and the second main electrode extension, wherein the first and/or second recesses comprise a sloped sidewall, and wherein the first and/or second recesses remain unfilled.
 2. The semiconductor device of claim 1, wherein each recess has a depth between about 0.5 and 5 nanometers.
 3. The semiconductor device of claim 1, wherein the control electrode has a length of less than about 100 nm.
 4. The semiconductor device of claim 1, wherein the control electrode has a length of less than about 50 nm.
 5. The semiconductor device of claim 1, wherein the overlap between the insulating layer and each main electrode extension is between about 10 and 20% of a length of the control electrode.
 6. The semiconductor device of claim 1, wherein an overlap between the control electrode and the first and second main electrode extensions is between about 10 and 20% of a length of the control electrode.
 7. The semiconductor device of claim 1, wherein the insulating layer comprises silicon oxide.
 8. The semiconductor device of claim 1, wherein the control electrode comprises silicon.
 9. The semiconductor device of claim 1, wherein the control electrode comprises a polycrystalline material.
 10. A semiconductor device comprising: a first main electrode extension and a second main electrode extension formed in a semiconductor substrate; an insulating layer formed on the semiconductor substrate; a control electrode formed over the insulating layer; and a spacer for deep source and drain implants; wherein the insulating layer has an overlap with each main electrode extension and the insulating layer has a first unfilled recess near the first main electrode extension having a depth of less than a width of an overlap between the control electrode and the first main electrode extension and/or a second unfilled recess near the second main electrode extension having a depth of less than a width of an overlap between the control electrode and the second main electrode extension, wherein the first and/or second recesses comprise a sloped sidewall, and wherein the spacer does not fill the first and/or second recesses.
 11. A semiconductor device comprising: a first main electrode extension and a second main electrode extension formed in a semiconductor substrate; an insulating layer formed on the semiconductor substrate; and a control electrode formed over the insulating layer; wherein the insulating layer has an overlap with each main electrode extension and the insulating layer has a first recess near the first main electrode extension having a depth of less than a width of an overlap between the control electrode and the first main electrode extension and/or a second recess near the second main electrode extension having a depth of less than a width of an overlap between the control electrode and the second main electrode extension, and wherein the first and/or second recesses comprise a sloped sidewall.
 12. The device of claim 11, wherein the sloped sidewall tapers inward in the direction of the semiconductor substrate. 